Wireless communication system using multiple-serving nodes

ABSTRACT

Methods, devices and systems for a wireless communication system using multiple-serving nodes are provided. In one embodiment, a method of wireless communication comprises sending from a wireless device an uplink control signal to a first node via a second node using a second communication link; receiving by said wireless device a downlink control signal from said first node using a first communication link; sending from said wireless device another uplink control signal to said second node using said second communication link; and receiving by said wireless device another downlink control signal from said second node via said first node using said first communication link.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. patent application Ser. No.12/759,383 filed Apr. 13, 2010 by Yi Yu, et al. entitled “WirelessCommunication System Using Multiple-Serving Nodes” (Attorney Docket No.37696-US-PAT-4214-32000), which is incorporated by reference herein asif reproduced in its entirety.

FIELD

The invention generally relates to wireless communication and inparticular to a wireless communication system using multiple-servingnodes.

BACKGROUND

Wireless communication systems are widely deployed to provide, forexample, a broad range of voice and data-related services. Typicalwireless communication systems consist of multiple-access communicationnetworks that allow users to share common network resources. Examples ofthese networks are time division multiple access (“TDMA”) systems, codedivision multiple access (“CDMA”) systems, single-carrier frequencydivision multiple access (“SC-FDMA”) systems, orthogonal frequencydivision multiple access (“OFDMA”) systems, or other like systems. AnOFDMA system is adopted by various technology standards such as evolveduniversal terrestrial radio access (“E-UTRA”), Wi-Fi, worldwideinteroperability for microwave access (“WiMAX”), ultra mobile broadband(“UMB”), and other similar systems. Further, the implementations ofthese systems are described by specifications developed by variousstandards bodies such as the third generation partnership project(“3GPP”) and 3GPP2.

As wireless communication systems evolve, more advanced networkequipment is introduced that provide improved features, functionality,and performance. A representation of such advanced network equipment mayalso be referred to as long-term evolution (“LTE”) equipment orlong-term evolution advanced (“LTE-A”) equipment. LTE is the next stepin the evolution of high-speed packet access (“HSPA”) with higheraverage and peak data throughput rates, lower latency and a better userexperience especially in high-demand urban areas. LTE accomplishes thishigher performance with the use of broader spectrum bandwidth, OFDMA andSC-FDMA air interfaces, and advanced antenna methods. Uplink (“UL”)refers to communication from a wireless device to a node. Downlink(“DL”) refers to communication from a node to a wireless device.

For a wireless communication system using a relay node (“RN”), awireless device may have difficulties selecting between a base stationand the RN due to, for instance, UL and DL power imbalance. An RN suchas an LTE Type-I RN can operate as a smaller base station. In an LTEsystem, a wireless device may choose a base station or RN based on theaverage DL signal strength, which may result in lower signal strength onthe UL due to the UL/DL power imbalance. Alternatively, the wirelessdevice may choose the base station or RN based on both DL and UL signalstrengths.

As described in the LTE-A standard, a Type-I RN can have full radioresource control (“RRC”) functionality. Such RN can control its cell andcan have its own physical cell identifier. Further, such RN can transmitits own synchronization channel and reference signal. Also, the wirelessdevice can receive, for instance, scheduling information and hybridautomatic repeat request (“HARQ”) feedback from the RN and send controlinformation such as a scheduling request (“SR”) signal, channel qualityindicator (“CQI”) signal and HARQ feedback signal to the RN.

In a heterogeneous LTE-A network using a plurality of base stations andType-I RNs, such network may have a significant difference between basestation transmission power and RN transmission power. A wireless devicemay provide a UL transmission that is received by a base station and aRN. The received power from such transmission may be substantiallydependent on the propagation path between the wireless device and thebase station, RN or both. In some circumstances, the wireless device mayreceive a stronger DL transmission from the base station, while the RNreceives a stronger UL transmission from the wireless device, leading toa UL and DL power imbalance. This disclosure describes variousembodiments including for resolving such power imbalance in amultiple-serving node wireless communication system.

BRIEF DESCRIPTION OF THE DRAWINGS

To facilitate this disclosure being understood and put into practice bypersons having ordinary skill in the art, reference is now made toexemplary embodiments as illustrated by reference to the accompanyingfigures. Like reference numbers refer to identical or functionallysimilar elements throughout the accompanying figures. The figures alongwith the detailed description are incorporated and form part of thespecification and serve to further illustrate exemplary embodiments andexplain various principles and advantages, in accordance with thisdisclosure, where:

FIG. 1 is a block diagram of one embodiment of a wireless communicationsystem using multiple-serving nodes in accordance with various aspectsset forth herein.

FIG. 2 illustrates one embodiment of a channel structure in a wirelesscommunication system using multiple-serving nodes in accordance withvarious aspects set forth herein.

FIG. 3 illustrates another embodiment of a channel structure in awireless communication system using multiple-serving nodes in accordancewith various aspects set forth herein.

FIG. 4 illustrates one embodiment of an independent control channelstructure in a wireless communication system using multiple-servingnodes in accordance with various aspects set forth therein.

FIG. 5 illustrates another embodiment of the independent control channelstructure in a wireless communication system using multiple-servingnodes in accordance with various aspects set forth therein.

FIG. 6 illustrates another embodiment of an independent control channelstructure in a wireless communication system using multiple-servingnodes in accordance with various aspects set forth therein.

FIG. 7 illustrates another embodiment of an independent control channelstructure in a wireless communication system using multiple-servingnodes in accordance with various aspects set forth herein.

FIG. 8 illustrates one embodiment of a distributed control channelstructure in a wireless communication system using multiple-servingnodes in accordance with various aspects set forth herein.

FIG. 9 illustrates another embodiment of a distributed control channelstructure in a wireless communication system using multiple-servingnodes in accordance with various aspects set forth herein.

FIG. 10 illustrates another embodiment of a distributed control channelstructure in a wireless communication system using multiple-servingnodes in accordance with various aspects set forth herein.

FIG. 11 is a flow chart of one embodiment of a method of providing datasignals in a wireless communication system using multiple-serving nodesin accordance with various aspects set forth herein.

FIG. 12A is a flow chart of one embodiment of a method of providingcontrol signals between a first node and a wireless device in a wirelesscommunication system using multiple-serving nodes in accordance withvarious aspects set forth herein.

FIG. 12B is a flow chart of another embodiment of a method of providingcontrol signals between a first node and a wireless device in a wirelesscommunication system using multiple-serving nodes in accordance withvarious aspects set forth herein.

FIG. 13A is a flow chart of one embodiment of a method of providingcontrol signals between a second node and a wireless device in awireless communication system using multiple-serving nodes in accordancewith various aspects set forth herein.

FIG. 13B is a flow chart of another embodiment of a method of providingcontrol signals between a second node and a wireless device in awireless communication system using multiple-serving nodes in accordancewith various aspects set forth herein.

Skilled artisans will appreciate that elements in the accompanyingfigures are illustrated for clarity, simplicity and to further helpimprove understanding of the embodiments, and have not necessarily beendrawn to scale.

DETAILED DESCRIPTION

Although the following discloses exemplary methods, devices and systemsfor use in wireless communication systems, it may be understood by oneof ordinary skill in the art that the teachings of this disclosure arein no way limited to the examplaries shown. On the contrary, it iscontemplated that the teachings of this disclosure may be implemented inalternative configurations and environments. For example, although theexemplary methods, devices and systems described herein are described inconjunction with a configuration for aforementioned wirelesscommunication systems, the skilled artisan will readily recognize thatthe exemplary methods, devices and systems may be used in other systemsand may be configured to correspond to such other systems as needed.Accordingly, while the following describes exemplary methods, devicesand systems of use thereof, persons of ordinary skill in the art willappreciate that the disclosed examplaries are not the only way toimplement such methods, devices and systems, and the drawings anddescriptions should be regarded as illustrative in nature and notrestrictive.

Various techniques described herein can be used for various wirelesscommunication systems. The various aspects described herein arepresented as methods, devices and systems that can include a number ofcomponents, elements, members, modules, nodes, peripherals, or the like.Further, these methods, devices and systems can include or not includeadditional components, elements, members, modules, nodes, peripherals,or the like. In addition, various aspects described herein can beimplemented in hardware, firmware, software or any combination thereof.It is important to note that the terms “network” and “system” can beused interchangeably. Relational terms described herein such as “above”and “below”, “left” and “right”, “first” and “second”, and the like maybe used solely to distinguish one entity or action from another entityor action without necessarily requiring or implying any actual suchrelationship or order between such entities or actions. The term “or” isintended to mean an inclusive “or” rather than an exclusive “or.”Further, the terms “a” and “an” are intended to mean one or more unlessspecified otherwise or clear from the context to be directed to asingular form. It is important to note that the terms “network” and“system” can be used interchangeably.

Wireless communication networks typically consist of a plurality ofwireless devices and a plurality of nodes. A node may also be called abase station, node-B (“NodeB”), base transceiver station (“BTS”), accesspoint (“AP”), cell, relay node (“RN”), serving node or some otherequivalent terminology. Further, the term “cell” can include a specificbase station, a specific sector of a base station, a specific antenna ofa sector of a base station. A base station typically contains one ormore radio frequency (“RF”) transmitters and receivers to communicatewith wireless devices. Further, a base station is typically fixed andstationary. For LTE and LTE-A equipment, the base station is alsoreferred to as an E-UTRAN NodeB (“eNB”).

A wireless device used in a wireless communication network may also bereferred to as a mobile station (“MS”), a terminal, a cellular phone, acellular handset, a personal digital assistant (“PDA”), a smartphone, ahandheld computer, a desktop computer, a laptop computer, a tabletcomputer, a set-top box, a television, a wireless appliance, or someother equivalent terminology. A wireless device may contain one or moreRF transmitters and receivers, and one or more antennas to communicatewith a base station. Further, a wireless device may be fixed or mobileand may have the ability to move through a wireless communicationnetwork. For LTE and LTE-A equipment and for various industry standards,the wireless device is also referred to as user equipment (“UE”).

FIG. 1 is a block diagram of one embodiment of wireless communicationsystem 100 using multiple-serving nodes in accordance with variousaspects set forth herein. In FIG. 1, system 100 can include a wirelessdevice 101, a first node 121 and a second node 141. In FIG. 1, wirelessdevice 101 can include processor 102 coupled to memory 103, input/outputdevices 104, transceiver 105 or any combination thereof, which can beutilized by wireless device 101 to implement various aspects describedherein. Transceiver 105 of wireless device 101 can include one or moretransmitters 106 and one or more receivers 107. Further, associated withwireless device 101, one or more transmitters 106 and one or morereceivers 107 can be connected to one or more antennas 109.

In FIG. 1, first node 121 can include processor 122 coupled to memory123 and transceiver 125. Transceiver 125 of first node 121 can includeone or more transmitters 126 and one or more receivers 127. Further,associated with first node 121, one or more transmitters 126 and one ormore receivers 127 can be connected to one or more antennas 129.

Similarly, second node 141 can include processor 122 coupled to memory123 and transceiver 125. Transceiver 125 of second node 141 includes oneor more transmitters 126 and one or more receivers 127. Further,associated with second node 141, one or more transmitters 126 and one ormore receivers 127 are connected to one or more antennas 129.

In this embodiment, wireless device 101 can communicate with first node121 using one or more antennas 109 and 129, respectively, over firstcommunication link 170, and can communicate with second node 141 usingone or more antennas 109 and 129, respectively, over secondcommunication link 180. Further, first node 121 can communicate withsecond node 141 using backhaul interfaces 128 over third communicationlink 190. First communication link 170 supports the communication ofsignals between wireless device 101 and first node 121. Secondcommunication link 180 supports the communication of signals betweenwireless device 101 and second node 141. Third communication link 190supports the communication of signals between first node 121 and secondnode 141. First communication link 170, second communication link 180and third communication link 190 can support, for instance, sending a DLdata signal, UL data signal, DL control signal, UL control signal, othersignal or combination of signals. Further, first communication link 170,second communication link 180 and third communication link 190 caninclude a physical channel, a logical channel, other channel or anycombination thereof. First communication link 170 and secondcommunication link 180 can use, for instance, any wireless communicationprotocol supporting technologies associated with, for instance, TDMA,CDMA, UMTS, Wi-MAX, LTE, LTE-A, Wi-Fi, Bluetooth or other similartechnology. Third communication link 190 can use any wired communicationprotocol, wireless communication protocol or both.

In this embodiment, first node 121, second node 141 or both cancommunicate a DL data signal, UL data signal, DL control signal, ULcontrol signal, other signal or any combination thereof with wirelessdevice 101. Therefore, such embodiment can allow wireless device 101 touse, for instance, the same or different nodes 121 and 141 tocommunicate a DL data signal, UL data signal, DL control signal, ULcontrol signal, other signal or any combination thereof. Determinationof which node 121 and 141 to use for any such signals can be determinedusing, for instance, a received signal strength, data throughput rate,bit error rate (“BER”), word error rate (“WER”), other similar metric orcombination of metrics.

For example, first node 121 can send a DL control signal to wirelessdevice 101 using first communication link 170. Once received, processor102 of wireless device 101 can process the received DL control signal,can generate a response, and can provide such response to first node 121using, for instance, a UL control signal of first communication link170.

In another example, wireless device 101 can send a UL control signal tosecond node 141 using second communication link 180. Once received,processor 142 of second node 141 can forward such signal to first node121 using third communication link 190.

FIG. 2 illustrates one embodiment of channel structure 200 of system 100in accordance with various aspects set forth herein. In this embodiment,structure 200 can allow first node 121 to provide a DL signal 210 towireless device 101 using first communication link 170, and can allowwireless device 101 to provide a UL signal 230 to second node 141 usingsecond communication link 180. A DL signal can include a DL data signal,DL control signal, other signal or any combination thereof. An UL signalcan include a UL data signal, UL control signal, other signal or anycombination thereof. For example, first node 121 can send a DL datasignal to wireless device 101 using first communication link 170.Further, structure 200 can allow wireless device 101 to send a UL datasignal to second node 141 using second communication link 180. Suchconfiguration can be advantageous when wireless device 101 is in closerproximity to second node 141 than first node 121 but still receiving astrong DL signal from node 121, allowing wireless device 101 to, forinstance, operate at a lower transmit power, higher data throughputrate, other benefit or any combination thereof.

In another embodiment, structure 200 can allow first node 121 and secondnode 141 to be one and the same node. In this configuration, nodes 121and 141 can act as, for instance, a single serving node as described in3rd Generation Partnership Project; Technical Specification Group RadioAccess Network; Physical Channels and Modulation (Release 8), 3GPP, or3GPP TS 36 series of specifications. It is important to recognize thateach node 121 and 141 may send a DL signal to wireless device 101, mayreceive a UL signal from wireless device 101 or both and may do the samefor another wireless device. Further, this disclosure can provide theadvantage of allowing full frequency re-use, frequency provisioning orboth for each node 121 and 141.

FIG. 3 illustrates another embodiment of channel structure 300 of system100 in accordance with various aspects set forth herein. In FIG. 3,structure 300 can allow first node 121 to send a DL data signal towireless device 101 using, for instance, a physical DL shared channel(“PDSCH”) 310 of first communication link 170. Similarly, system 300 canallow wireless device 101 to send a UL data signal to second node 141using, for instance, physical UL shared channel (“PUSCH”) 320 of secondcommunication link 180. Such configuration can be advantageous byallowing the assignment of PDSCH 310, PUSCH 320 or both based on, forinstance, the quality of the associated communication link. However,assigning the sending of a UL data signal and the sending of a DL datasignal to different nodes can impact, for instance, the control channelstructure of system 300. For example, the control channel structure usedin LTE Release 8 is designed for a wireless communication system usingsingle-serving nodes and would need to be modified, as described by thisdisclosure, to support multiple-serving node wireless communicationsystem 100. For instance, first node 121 may provide a UL grant signal,DL grant signal or both to wireless device 101 using a DL controlchannel of first communication link 170. Under system 100, such grantsmay be provided from different nodes 121 and 141, as opposed to the samenode. Further, any timing requirements such as the UL timing alignmentprocedure described in LTE Release 8 may not be supported in system 100since the transmission of DL signals, UL signals or both may beassociated with different nodes. Other issues may exist, for instance,with the configuration and use of UL control channels and DL controlchannels, including defining the proper control channel to send anacknowledgment or no acknowledgment (“ACK/NACK”) signal, soundingreference signal (“SRS”) signal, other signal or combination of signals.

This disclosure includes describing two alternative control channelstructures to resolve the aforementioned issues. Such alternatives areassociated with an independent control channel structure and adistributed control channel structure. FIG. 4 illustrates one embodimentof independent control channel structure 400 of system 100 in accordancewith various aspects set forth therein. In FIG. 4, first communicationlink 170 can include PDSCH 310, physical DL control channel (“PDCCH”)430, physical UL control channel (“PUCCH”) 450, physical hybridautomatic repeat request indicator channel (“PHICH”) 470, other channelor any combination thereof. Second communication link 180 can includePUSCH 320, PDCCH 440, PUCCH 460, physical hybrid automatic repeatrequest (“HARQ”) indicator channel (“PHICH”) 480 or any combinationthereof. For communication of data signals, structure 400 can allowfirst node 121 to provide a DL data signal to wireless device 101 using,for instance, PDSCH 310 of first communication link 170. Further,wireless device 101 can provide a UL data signal to second node 141using, for instance, PUSCH 320 of second communication link 180. Forcommunication of control signals, structure 400 can allow first node 121and second node 141 each to have the same or different control channelstructure. For example, first node 121 can provide a DL control signalto wireless device 101 using, for instance, PDCCH 430 of firstcommunication link 170. Wireless device 101 can provide a UL controlsignal to first node 121 using, for instance, PUCCH 450 of firstcommunication link 170. Further, second node 141 can provide a DLcontrol signal to wireless device 101 using, for instance, PDCCH 440,PHICH 480 or both of second communication link 180. Further, wirelessdevice 101 can provide a UL control signal to second node 141 using, forinstance, PUCCH 460 of second communication link 180.

FIG. 5 illustrates another embodiment of independent control channelstructure 500 of system 100 in accordance with various aspects set forththerein. In FIG. 5, structure 500 can allow first node 121 to providewireless device 101 a DL control signal using, for instance, PDCCH 430of first communication link 170. Similarly, structure 500 can allowsecond node 141 to provide wireless device 101 a DL control signalusing, for instance, PDCCH 440 of second communication link 180. It isimportant to recognize that the DL control signal provided by first node121 and the DL control signal provided by second node 141 areindependent of each other. First node 121 can manage, control,coordinate, schedule or any combination thereof the transmission of a DLdata signal to wireless device 101 using, for instance, PDSCH 310 offirst communication link 170. Further, second node 141 can manage,control, coordinate, schedule or any combination thereof thetransmission of a UL data signal from wireless device 101 using, forinstance, PUSCH 320 of second communication link 180. For example, firstnode 121 can provide a DL grant signal to wireless device 101 using, forinstance, PDCCH 430 of first communication link 170. Further, secondnode 141 can provide a UL grant signal to wireless device 101 using, forinstance, PDCCH 440 of second communication link 180. A DL grant signalcan provide permission for first node 121 to send a DL data signal towireless device 101 using, for instance, PDSCH 310 of firstcommunication link 170. A UL grant signal can provide permission forwireless device 101 to send a UL data signal to second node 141 using,for instance, PUSCH 320 of second communication link 180.

FIG. 6 illustrates another embodiment of independent control channelstructure 600 of system 100 in accordance with various aspects set forththerein. In FIG. 6, structure 600 can allow first communication link 170to include PDSCH 310, PDCCH 430, PUCCH 450, other channel or anycombination thereof. For instance, wireless device 101 can provide a ULcontrol signal to first node 121 using, for instance, PUCCH 450 of firstcommunication link 170. Such UL control signal can include, forinstance, a channel quality indicator (“CQI”) signal, pre-coding matrixindicator (“PMI”) signal, rank indication (“RI”) signal, ACK/NACKsignal, other signal or combination of signals. The CQI, PMI, RI andACK/NACK signals can be used to support, for instance, the transmissionfrom first node 121 of a DL data signal to wireless device 101 using,for instance, PDSCH 310 of first communication link 170. Further, powercontrol signals can be used to support, adjust, adapt, coordinate or anycombination thereof the transmission of UL signals from wireless device101 to first node 121. First node 101 can provide a DL control signal towireless device 101 using, for instance, PDCCH 430 of firstcommunication link 170, wherein the DL control signal can include apower control signal such as a transmission power control command(“TPC”) signal.

FIG. 7 illustrates another embodiment of independent control channelstructure 700 of system 100 in accordance with various aspects set forthherein. In FIG. 7, structure 700 can allow second communication link 180to include PUSCH 420, PDCCH 440, PUCCH 460 and PHICH 480, other channelor any combination thereof. In FIG. 7, structure 700 can allow wirelessdevice 101 to provide a UL control signal to second node 141 using, forinstance, PUCCH 460 of second communication link 180. Further, secondnode 141 can manage, support, coordinate or any combination thereofreceiving a UL data signal from wireless device 101 using, for instance,PUSCH 320 of second communication link 180 by providing a DL controlsignal to wireless device 101 using, for instance, PDCCH 440, PHICH 480or both of second communication link 180. For example, PHICH 480 ofsecond communication link 180 can be used to deliver, for instance, anACK/NACK signal from second node 141 to wireless device 101, and PDCCH440 can be used to deliver, for instance, a UL grant signal, ACK/NACKsignal, TPC signal, timing adjustment command signal, other signal orany combination thereof from second node 141 to wireless 101. Further,PUCCH 460 can be used to deliver, for instance, scheduling request(“SR”) signal, SRS signal, other signal or any combination thereof fromwireless device 101 to second node 141. For example, an SR signal caninclude the scheduling request indicator (“SRI”) signal associated withsending, for instance, a UL data signal from wireless device 101 tosecond node 141. Further, wireless device 101 can send an SRS signal tosecond node 141 to allow for timing adjustment, UL transmissionadaptation, other benefit or any combination thereof between wirelessdevice 101 and second node 141. It is important to recognize that thetransmission of a dedicated SRS signal from wireless device 101 to firstnode 121 may not be required, since any timing alignment is intended forUL transmissions from wireless device 101 to second node 141. However,the timing alignment required for first node 121 may cause interferencewith other wireless devices transmitting to first node 121. Knowledge ofthe UL transmission timing may be useful to mitigate such interference.Therefore, such transmission timing can be estimated using, forinstance, the timing of PUCCH 460 transmissions from wireless device 101to second node 141.

In another embodiment, wireless device 101 may multiplex control signalswith data signals using, for instance, PUSCH 320 of second communicationlink 180, PDSCH 310 of first communication link 170 or both. Forexample, after receiving a UL data signal and a UL control signal usingPUSCH 320, second node 141 may forward the UL control signal to firstnode 121 using, for instance, backhaul link 330 of third communicationlink 190. If the UL control signal is an ACK/NACK signal, backhaul link330 may increase the HARQ re-transmission delay. In order to avoidwasting DL bandwidth, the number of HARQ re-transmissionprocedure-related processes can be increased to accommodate longer HARQre-transmission round trip time (“RTT”). For example, the controlsignals used for independent control channel structure 600 of firstcommunication link 170 are provided in Table 1.

TABLE 1 CONTROL CHANNEL CONTROL SIGNAL PDCCH 430 DL grant signal, TPCsignal PUCCH 450 ACK/NACK signal, CQI signal, PMI signal, RI signalPHICH 470 ACK/NACK signal

Further, control signals for independent control channel structure 700of second communication link 180 are provided in Table 2.

TABLE 2 CONTROL CHANNEL CONTROL SIGNAL PDCCH 440 UL grant signal, TPCsignal, ACK/NACK signal PUCCH 460 SR signal, SRS signal PHICH 480ACK/NACK signal

FIG. 8 illustrates one embodiment of distributed control channelstructure 800 of system 100 in accordance with various aspects set forthherein. In this embodiment, first node 121 can schedule DL transmissionsand second node 141 can schedule UL transmissions for wireless device101. Further, structure 800 can allow first node 121 to send a DL signalto wireless device 101 using first communication link 170. However,wireless device 101 cannot send a UL signal to first node 121 usingfirst communication link 170. Instead, wireless device 101 can send a ULsignal to first node 121 via second node 141 using second communicationlink 180 and third communication link 190. Similarly, structure 800 canallow wireless device 101 to send a UL signal to second node 141 usingsecond communication link 180. However, second node 141 cannot send a DLsignal to wireless device 101 using second communication link 180.Instead, second node can send a DL signal to wireless device 101 viafirst node 121 using third communication link 190 and firstcommunication link 170. To summarize, any transmission between firstnode 121 and wireless device 101 using first communication link 170 mayonly be the transmission of a DL signal from first node 121 to wirelessdevice 101. Further, any transmission between second node 141 andwireless device 101 using second communication link 180 may only be thetransmission of a UL signal from wireless device 101 to second node 141.In this embodiment, wireless device 101 can be assigned first node 121,second node 141 or both based on the quality of the correspondingcommunication link 170 and 180, wherein the quality of communicationlink 170 and 180 can be determined using, for instance, the receivedsignal strength, signal quality, data throughput rate, bit error rate(“BER”), word error rate (“WER”), other similar metric or anycombination thereof. In some embodiments, first node 121 and second node141 may be the same node.

In FIG. 8, structure 800 can allow wireless device 101 to send a ULcontrol signal to first node 121 via second node 141 using secondcommunication link 180 and third communication link 190, wherein the ULcontrol signal can include, for instance, an ACK/NACK signal, CQIsignal, PMI signal, RI signal, other signal or any combination thereof.For example, wireless device 101 can send a UL control signal to secondnode 141 using, for instance, PUCCH 460 of second communication link180. Further, second node 141 can forward the UL control signal to firstnode 121 using, for instance, backhaul channel 330 of thirdcommunication link 190.

In FIG. 8, structure 800 can allow second node 141 to send a DL controlsignal to wireless device 101 via first node 121 using thirdcommunication link 190 and first communication link 170, wherein the DLcontrol signal can include, for instance, a UL grant signal, ACK/NACKsignal, TPC signal, other control signal or any combination thereof. Forexample, second node 141 can send a DL control signal to first node 121using, for instance, backhaul channel 330 of third communication link190. Further, first node 121 can forward the DL control signal towireless device 101 using, for instance, PDCCH 430, PHICH 470 or both offirst communication link 170. It is important to recognize that carefulcoordination, management, assignment or any combination thereof of theDL and UL control signals may be required to deliver the correct controlsignal to the correct node.

FIG. 9 illustrates another embodiment of distributed control channelstructure 900 of system 100 in accordance with various aspects set forthherein. In FIG. 9, structure 900 can allow first node 121 to schedulethe transmission of a DL signal from first node 121 to wireless device101 using first communication link 170 and can allow second node 141 toschedule the transmission of a UL signal from wireless device 101 tosecond node 141 using second communication link 180. For instance, firstnode 121 can send a DL signal to wireless device 101 using firstcommunication link 170.

In another embodiment, second node 141 can determine the scheduling ofthe transmission of a UL signal by wireless device 101 to second node141 using second communication link 180 and provide such scheduling tofirst node 121, where first node 121 can provide a corresponding ULgrant signal to wireless device 101 using, for instance, PDCCH 430 offirst communication link 170. It is important to recognize that thescheduling of the transmission of a UL signal from wireless device 101to second node 141 using second communication link 180 is determined bysecond node 141 but sent to wireless device 101 via first node 121using, for instance, PDCCH 430 of first communication link 170.

In another embodiment, second node 141 can determine a UL power controlsignal associated with, for instance, PUSCH 320, PUCCH 460, otherchannel or any combination thereof transmitted by wireless device 101 tosecond node 141 using second communication link 180. Further, secondnode 141 can provide such UL power control signal to wireless device 101via first node 121 using, for instance, backhaul channel 330 of thirdcommunication link 190 and PDCCH 430 of first communication link 170.

In another embodiment, transmission delay using backhaul channel 330 ofthird communication link 190 may require second node 141 to provideadditional time for scheduling the transmission of a UL signal fromwireless device 101 to second node 141 using second communication link180. For example, second node 141 can schedule the transmission of a ULsignal by a predetermined amount of time after second node 141 sends,for instance, a UL grant signal to wireless device 101 via first node121, wherein the predetermined amount of time can correspond to, forinstance, processing time, transmission delay, other delay, or anycombination thereof.

In another embodiment, the resources associated with, for instance, anSRS signal, PUCCH 460, other channel, or any combination thereof can beallocated by second node 141 but delivered to wireless device 101 viafirst node 121. In this embodiment, wireless device 101 can provide a ULcontrol signal to second node 141 using, for instance, PUCCH 460 ofsecond communication link 180, wherein the UL control signal caninclude, for instance, a HARQ feedback signal, CQI signal, PMI signal,RI signal, SR signal, other signal or any combination thereof. Forexample, second node 141 can assign an SRS signal, PUCCH 460, otherresource or any combination thereof for wireless device 101 and sendsuch resource assignment to first node 141 using backhaul channel 330 ofthird communication link 190. First node 121 can then send theconfiguration of the HARQ feedback signal, CQI signal, PMI signal, RIsignal, SR signal, other signal or any combination thereof to wirelessdevice 101 using, for instance, DL RRC signaling, other signaling orboth. To summarize, the resources for an SRS signal, PUCCH 460, otherchannel, or any combination thereof can be allocated by second node 141and delivered to wireless device 101 via first node 121.

FIG. 10 illustrates another embodiment of distributed channel structure1000 of system 100 in accordance with various aspects set forth herein.In this embodiment, first node 121 can transmit a DL data signal towireless device 101 using first communication link 170. In response tosuch transmission, wireless device 101 can send a HARQ feedback signalto first node 121 via second node 141. First node 121 can then determinewhether to re-transmit the DL data signal to wireless device 101. Forexample, first node 121 can transmit a DL data signal to wireless device101 using, for instance, PDSCH 310 of first communication link 170. Inresponse to such transmission, wireless device 101 can send a HARQfeedback signal to second node 141 using, for instance, PUCCH 460 ofsecond communication link 180. Further, second node 141 can forward theHARQ feedback signal to first node 121 using backhaul channel 330 ofthird communication link 190. First node 121 can then determine whetherto re-transmit the DL data signal to wireless device 101 using, forinstance, PDSCH 310 of first communication link 170.

In another embodiment, transmission delay associated with forwarding aDL HARQ feedback signal such as an ACK/NAK signal from second node 121to first node 141 using, for instance, backhaul channel 330 of thirdcommunication link 190 may require increasing the number of DL HARQre-transmission procedure-related processes to optimize the use ofavailable bandwidth. Further, the DL HARQ re-transmission procedure cansupport asynchronous re-transmission to allow, for instance, first node121 to schedule a re-transmission of a DL signal for wireless device 101upon receiving the forwarded DL HARQ feedback signal from second node141.

In another embodiment, instead of using PHICH 470, a UL grant signal maybe sent by first node 121 to wireless device 101 each time are-transmission of a UL signal is required. Unlike the synchronous ULHARQ re-transmission procedure described in, for instance, LTE Release8, wireless device 101 may not perform a re-transmission of a UL signalunless a re-transmission UL grant signal is received by wireless device101 from first node 121. Wireless device 101 can transmit a UL signal tosecond node 141 after receiving a UL grant signal from second node 141via first node 121. Upon receiving the UL signal, instead of sending aUL HARQ feedback signal such as an ACK/NACK signal to wireless device101 via first node 121, second node 141 can send a new data indicator(“NDI”) signal to wireless device 101 via first node 121 to indicate thescheduling for transmission of a new UL signal. For an unsuccessfultransmission of a UL signal from wireless device 101, second node 141can send a new UL grant signal to wireless device 101 via first node 121to schedule UL re-transmission for wireless device 101. The UL grantsignal can include a NDI signal, wherein the NDI signal can be used toindicate whether the UL grant signal is associated with a newtransmission or a re-transmission of a UL signal. Further, a HARQprocess identifier signal may be included with the UL grant signal. Suchmethod can allow wireless device 101 to keep the UL signal in, forinstance, memory 103, so that the UL signal is available for a UL HARQre-transmission procedure-related process. Such memory may be re-usedonce a UL grant signal for a new data transmission is received using,for instance, PDCCH 430 of first transmission link 170. Further,avoiding the use of PHICH 470 via first communication link 170 cansimplify the operation of first node 121 by not requiring it toconfigure and use PHICH 470 associated with the transmission of PUSCH320.

In another embodiment, wireless device 101 can send to first node 121via second node 141 a PMI signal, CQI signal, RI signal, other signal orany combination thereof associated with the transmission of a DL signalfrom first node 121 to wireless device 101 via first communication link170.

In another embodiment, for the transmission of a UL signal by wirelessdevice 101 using second communication link 180, second node 141 canmeasure the channel quality using, for instance, the SRS signal receivedfrom wireless device 101. A person of ordinary skill in the art willrecognize that there are many methods of measuring channel quality usinga received reference signal. Using such channel quality measurement,second node 141 can determine an appropriate modulation and codingscheme (“MCS”) for the transmission of a UL signal from wireless device101. Further, second node 141 may include additional time for schedulingthe transmission of a UL signal from wireless device 101 to compensatefor any delay associated with second node 141 sending the associated ULgrant signal to wireless device 101 via first node 121 using, forinstance, backhaul channel 330 of third communication link 190. This mayrequire second node 141 to perform the scheduling in advance and have agood estimation of the transmission delay on backhaul channel 330 ofthird communication link 190. Similarly, a TPC signal associated withthe transmission of a UL control signal from wireless device 101 tosecond node 121 using, for instance, PUCCH 460, PUSCH 320 or both ofsecond communication link 180 may be determined by second node 141 andsent to wireless device 101 via first node 121.

In another embodiment, first node 121 and second node 141 may be closelycoupled using, for instance, backhaul channel 330 of third communicationlink 190. In such configuration, backhaul channel 330 of thirdcommunication link 190 may experience more traffic than independentcontrol channel structure 400, 500, 600 and 700. In distributed controlchannel structure 800, a UL grant signal, TPC signal or both associatedwith PUSCH 320, PUCCH 460 or both may be transferred from second node141 to first node 121 using, for instance, backhaul channel 330 of thirdcommunication link 190. In addition, a HARQ feedback signal, PMI signal,CQI signal, RI signal, other signal or any combination thereof may betransferred from second node 141 to first node 121 using, for instance,backhaul channel 330 of third communication link 190. In thisembodiment, time delay in sending UL signals using, for instance,backhaul channel 330 of third communication link 190 may impact systemperformance. However, such time delay can be mitigated by using, forinstance, a fiber optic cable between backhaul interface 128 of firstnode 121 and second node 141.

Due to separating UL and DL transmissions between first node 121 andsecond node 141, time synchronization issues between wireless device 101and nodes 121 and 141 may occur. In one embodiment, nodes 121 and 141may be time synchronized. Such requirement may be inherent to variousindustry standards such as LTE-A for a Type-I relay network. Forexample, as described in the LTE and LTE-A standards, coordinatedmulti-point (“CoMP”) transmission, reception or both may require networktime synchronization. CoMP transmission, reception or both can be usedby LTE and LTE-A equipment to improve, for instance, data rates,cell-edge throughput, other benefit or any combination thereof. Further,such CoMP technique can be applied to multiple-serving node wirelesscommunication system 100, since first node 121 is on the routing pathand the data information, control information or both can be transmittedto second node 141 using, for instance, backhaul channel 330 of thirdcommunication link 190. In addition, as described in the LTE and LTE-Astandards, multimedia broadcast multicast service (“MBMS”) may requirenetwork time synchronization. MBMS uses a plurality of base stations,RNs or both to broadcast the same information to a wireless device. MBMSmay require a synchronized network so that a wireless device only needsto maintain time synchronization with one node.

In a synchronized network, wireless device 101 does not need to maintainseparate time synchronization with first node 121 and second node 141.Such requirement can simplify the design of wireless device 101. For anunsynchronized network using independent control channel structure 400,500, 600 and 700, wireless device 101 may need to maintain separate timesynchronization with first node 121 and second node 141. For anunsynchronized network using distributed control channel structure 800,900 and 1000, wireless device 101 may not need to maintain timesynchronization with second node 141, since second node 141 may nottransmit any DL signals to wireless device 101.

In an OFDM-based wireless communication system, cyclic prefix (“CP”) maybe added to an OFDM symbol to, for instance, reduce inter-symbolinterference, maintain orthogonality amongst the sub-carriers or both.In an LTE system, there can be a normal CP and an extended CP, whereinthe normal CP has a shorter length than the extended CP. LTE systems canuse an extended CP to support, for instance, larger cell sizes, MBMSservice, other benefit or any combination thereof. While the wirelesspropagation path between wireless device 101 and nodes 121 and 141 maycomprise multiple-paths, the length of the normal CP, extended CP orboth should be sufficient to support any delay between suchmultiple-paths, as specified for the LTE system.

In multiple-serving node wireless communication system 100, wirelessdevice 101 may receive transmissions from both first node 121 and secondnode 141 at the RRC-Connected state. For such case, the same CP lengthmay be applied to both nodes 121 and 141. Geometrically, first node 121and second node 141 may be placed within the size of the donor cell. Themultiple-path delay spread between wireless device 101 and first node121 and wireless device 101 and second node 141 may be different but canbe within the duration of the normal CP length or the extended CPlength. Extended CP length can be used for nodes 121 and 141 to mitigateany concerns associated with larger multiple-path delay spread.

Latency in multiple-serving node wireless communication system 100 mayimpact quality of service (“QoS”). In system 100, latency may increasedue to, for instance, using backhaul channel 330 of third communicationlink 190. In another embodiment, wireless device 101 may directlyconnect to first node 121 to transmit both DL and UL signals to reducelatency for a delay-sensitive network service. In this embodiment, firstnode 121 can be a base station and second node 141 can be an RN.

The control plane latency is typically determined as the transition timefrom idle state to active state. Even though multiple serving nodes maybe used by wireless device 100, wireless device 100 may still need touse a random access procedure to connect to first node 121. In the casethat wireless device 101 can only make channel quality measurements ofDL transmissions from first node 121 during an idle state and may onlytry to connect to first node 121 with the strongest received powerduring a transition period. After the RRC connection is obtained, firstnode 121 may negotiate with second node 141 associated with thetransmissions of a UL data signal and transition such UL transmissionsto another node. Therefore, the control plane latency should not changefor multiple-serving node wireless communication system 100.

The user plane latency can be defined as the one-way transit timebetween a session data unit (“SDU”) packet being available at theinternet protocol (“IP”) layer in wireless device 101 and beingavailable at the IP layer in node 121 and 141 or being available at theIP layer in node 121 and 141 and being available at the IP layer inwireless device 101. The user plane packet delay can include delayintroduced by, for instance, associated protocols, control signaling orboth. For independent control channel structure 400, 500, 600 and 700 ina multiple-serving node wireless communication system 100, there is noadditional delay for wireless device 100 compared to wireless device 101in a single-serving node wireless communication system. As discussedpreviously, two independent control channel structures 400, 500, 600 and700 are maintained for first communication link 100 and secondcommunication link 200 and no control signals are exchanged usingcommunication link 300.

For distributed control channel structure 800, 900 and 1000, additionaldelay may occur due to, for instance, the frequent exchange of controlsignals between second node 141 and first node 121 via thirdcommunication link 190. Such delay may be caused by, for instance,sending control signals such as a HARQ feedback signal, CQI signal, PMIsignal, RI signal, other control signal or any combination thereof tofirst node 121 or second node 141 and forwarding such signals to secondnode 141 or first node 121, respectively. For example, a 4 millisecond(“msec.”) delay associated with sending a control signal from secondnode 141 to first node 121 and a 2 msec. delay associated withprocessing time at first node 121 may require increasing the packetround trip time (“RTT”) from, for instance, eight msec. as specified by“LTE Release 8” to fourteen msec. Further, the number of HARQ processescan be increased to accommodate such increase in RTT so that nodes 121and 141 do not need to wait for the HARQ feedback signal forwarded fromthe other node 121 and 141 before transmitting a new packet. If thepacket is not received correctly by wireless device 101, first node 121or second node 141, then the re-transmission can occur six msec. laterthan the re-transmission in a single-serving node system. In LTE Release8, typically up to four re-transmissions are allowed for a voice over IP(“VoIP”) service. For multiple-serving node wireless communicationsystem 100, two re-transmissions may be allowed within such timingconstraints. To minimize reliance on the reduced number ofre-transmissions, for instance, a more conservative MCS for the initialtransmission by wireless device 101 can be used so that the packet canbe received correctly with higher probability for the initialtransmission.

In summary, splitting the reception of DL and UL transmissions fromwireless device 101 between first node 121 and second node 141 shouldnot incur additional control channel delay if independent controlchannel structure 400, 500, 600 and 700 is used. On the other hand, ifdistributed control channel structure 800, 900 and 1000 is used, thenumber of maximum re-transmissions allowed within a certain period canbe reduced. More conservative MCS selection may be considered for theinitial transmission in this case.

In another embodiment, wireless device 101 may be operated in conditionssuch that handoffs, handovers or both may affect its connection to firstnode 121, second node 141 or both. For example, wireless device 101 maybe required to handoff from first node 121 to another node, which wouldchange, for instance, the source of the DL data signal from first node121 to another node. Similarly, wireless device 101 may be required tohandoff from second node 141 to another node, which would change, forinstance, the source of the UL data signal from second node 141 toanother node. Further, wireless device 101 may be required to handofffrom first node 121 and second node 141 to different target nodes.Various handoff scenarios exist for wireless device 101 in system 100.For instance, wireless device 101 can handoff from second node 141 toanother second node, and can maintain its connection with first node121. Wireless device can handoff from first node 121 to another firstnode, and can maintain its connection with second node 141. Wirelessdevice 101 can handoff from second node 141 to first node 121. Wirelessdevice 101 can handoff from first node 121 to second node 141. Wirelessdevice 101 can handoff from first node 121 to another first node and canhandoff from second node 141 to another second node. Wireless device 101can handoff from first node 121 and second node 141 to the same servingnode. First node 121, second node 141 or both may need to indicate towireless device 101 which node will be handed-off This could be signaledvia high layer signaling such as RRC signaling. Further, morecoordination may be required when wireless device 101 simultaneously orcontemporaneously handoffs first node 121 and second node 141.

FIG. 11 is a flow chart of one embodiment of a method of providing datasignals in system 100 in accordance with various aspects set forthherein. In FIG. 11, method 1100 can start at, for instance, block 1110,where method 1100 can send a DL data signal from first node 121 towireless device 101 using first communication link 170. At block 1120,method 1100 can send a UL data signal from wireless device 101 to secondnode 141 using second communication link 180. At block 1130, method 1100can send the UL data signal from second node 141 to first node 121 usingthird communication link 190.

FIG. 12A is a flow chart of one embodiment of method 1200 a of providingcontrol signals between first node 121 and wireless device 101 in system100 in accordance with various aspects set forth herein. In FIG. 12A,method 1200 a can start at, for instance, block 1210, where method 1200a can send a DL control signal from first node 121 to wireless device101 using first communication link 170, wherein the DL control signalmay include, for instance, a DL grant signal, other control signal orboth. At block 1220, method 1200 a can send a UL control signal fromwireless device 101 to first node 121 using first communication link170, wherein the UL control signal can include, for instance, anACK/NACK signal, CQI signal, PMI signal, RI signal, other control signalor any combination thereof.

FIG. 12B is a flow chart of another embodiment of method 1200 b ofproviding control signals between first node 121 and wireless device 101in system 100 in accordance with various aspects set forth herein. InFIG. 12B, method 1200 b can start at, for instance, block 1230, wheremethod 1200 b can send a DL control signal from first node 121 towireless device 101 using first communication link 170, wherein the DLcontrol signal may include, for instance, a DL grant signal, othercontrol signal or both. At block 1240 and block 1260, method 1200 b cansend a UL control signal from wireless device 101 to first node 121 viasecond node 141, wherein the UL control signal can include, forinstance, an ACK/NACK signal, CQI signal, PMI signal, RI signal, othercontrol signal or any combination thereof. At block 1240, method 1200 bcan send the UL control signal from wireless device 101 to second node141 using second communication link 170. At block 1250, method 1200 bcan send the UL control signal from second node 141 to first node 121using third communication link 190.

FIG. 13A is a flow chart of one embodiment of method 1300 a of providingcontrol signals between second node 141 and wireless device 101 insystem 100 in accordance with various aspects set forth herein. In FIG.13A, method 1300 a can start at, for instance, block 1310, where method1300 a can send a UL control signal from wireless device 101 to secondnode 141 using second communication link 180, wherein the UL controlsignal may include an SR signal, SRS signal, other control signal or anycombination thereof. At block 1320, method 1300 b can send a DL controlsignal from second node 141 to wireless device 101 using secondcommunication link 180, wherein the DL control signal may include a ULgrant signal, ACK/NACK signal, TPC signal, other control signal or anycombination thereof.

FIG. 13B is a flow chart of another embodiment of method 1300 b ofproviding control signals between second node 141 and wireless device101 in system 100 in accordance with various aspects set forth herein.In FIG. 13B, method 1300 b can start at, for instance, block 1330, wheremethod 1300 b can send a UL control signal from wireless device 101 tosecond node 141 using second communication link 180, wherein the ULcontrol signal may include an SR signal, SRS signal, other controlsignal or any combination thereof. At block 1340 and block 1350, method1300 b can send a DL control signal from second node 141 to wirelessdevice 101 via first node 121, wherein the DL control signal mayinclude, for instance, a UL grant signal, ACK/NACK signal, TPC signal,other signal or any combination thereof. At block 1340, method 1300 bcan send the DL control signal from second node 141 to first node 121using third communication link 190. At block 1350, method 1300 b cansend the DL control signal from first node 121 to wireless device 101using first communication link 170.

Having shown and described exemplary embodiments, further adaptations ofthe methods, devices and systems described herein may be accomplished byappropriate modifications by one of ordinary skill in the art withoutdeparting from the scope of the present disclosure. Several of suchpotential modifications have been mentioned, and others may be apparentto those skilled in the art. For instance, the exemplars, embodiments,and the like discussed above are illustrative and are not necessarilyrequired. Accordingly, the scope of the present disclosure should beconsidered in terms of the following claims and is understood not to belimited to the details of structure, operation and function shown anddescribed in the specification and drawings.

As set forth above, the described disclosure includes the aspects setforth below.

What is claimed is:
 1. A method of communication in a Long TermEvolution (LTE) wireless communication system, the method comprising:receiving, by a wireless device, a first physical downlink controlchannel (PDCCH) and a first physical hybrid automatic repeat requestindicator channel (PHICH) from a first node while also receiving asecond PDCCH and a second PHICH from a second node; and transmitting, bythe wireless device, a first physical uplink control channel (PUCCH) tothe first node while also transmitting a second PUCCH to the secondnode.
 2. The method of claim 1, further comprising: receiving, by thewireless device, data in a physical downlink shared channel (PDSCH)transmitted from the first node; and transmitting, by the wirelessdevice, the data in a physical uplink shared channel (PUSCH) transmittedto the second node.
 3. The method of claim 2, wherein the first PDCCH,the first PHICH, and the PDSCH are multiplexed to be transmitted fromthe first node.
 4. The method of claim 2, wherein the second PUCCH andthe PUSCH are multiplexed to be transmitted to the second node.
 5. Themethod of claim 1, wherein the first PUCCH and the second PUCCH compriseat least one of: a sounding reference signal (SRS); an acknowledgment orno acknowledgment (ACK/NACK) signal; a channel quality indicator (CQI)signal; a precoding matrix indictor (PMI) signal; a rank indicator (RI)signal; or a scheduling request indicator (SRI) signal.
 6. The method ofclaim 1, wherein the first PDCCH and the second PDCCH comprise at leastone of: a downlink grant signal; an uplink grant signal; a timingadjustment signal; or a transmission power control (TPC) signal.
 7. Themethod of claim 1, wherein the first node and the second node are timesynchronized.
 8. The method of claim 2, further comprising selecting thefirst node to transmit the data using at least one of received signalstrength, bit error rate and word error rate.
 9. The method of claim 2,further comprising selecting the second node to receive the data usingat least one of received signal strength, bit error rate and word errorrate.
 10. A wireless device in a Long Term Evolution (LTE) wirelesscommunication system, the wireless device comprising: a processorcoupled to a memory containing processor-executable instructions,wherein the processor is configured to: receive a first physicaldownlink control channel (PDCCH) and a first physical hybrid automaticrepeat request indicator channel (PHICH) from a first nodesimultaneously with receiving a second PDCCH and a second PHICH from asecond node; and transmit a first physical uplink control channel(PUCCH) to the first node simultaneously with transmitting a secondPUCCH to the second node.
 11. The wireless device of claim 10, whereinthe wireless device receives data from the first node in a physicaldownlink shared channel (PDSCH) and transmits the data to the secondnode in a physical uplink shared channel (PUSCH).
 12. The wirelessdevice of claim 11, wherein the first PDCCH, the first PHICH, and thePDSCH are multiplexed to be transmitted from the first node.
 13. Thewireless device of claim 11, wherein the second PUCCH and the PUSCH aremultiplexed to be transmitted to the second node.
 14. The wirelessdevice of claim 10, wherein the first PUCCH and the second PUCCHcomprise at least one of: a sounding reference signal (SRS); anacknowledgment or no acknowledgment (ACK/NACK) signal; a channel qualityindicator (CQI) signal; a precoding matrix indictor (PMI) signal; a rankindicator (RI) signal; or a scheduling request indicator (SRI) signal.15. The wireless device of claim 10, wherein the first PDCCH and thesecond PDCCH comprise at least one of: a downlink grant signal; anuplink grant signal; a timing adjustment signal; or a transmission powercontrol (TPC) signal.
 16. A system of communication in a Long TermEvolution (LTE) wireless communication system, the system ofcommunication comprising: a wireless device; a first nodecommunicatively linked to the wireless device; and a second nodecommunicatively linked to the wireless device; wherein the first nodetransmits a first physical downlink control channel (PDCCH) and a firstphysical hybrid automatic repeat request indicator channel (PHICH) tothe wireless device simultaneously with the second node transmitting asecond PDCCH and a second PHICH to the wireless device; and wherein thewireless device transmits a first physical uplink control channel(PUCCH) to the first node simultaneously with transmitting a secondPUCCH to the second node.
 17. The system of communication of claim 16,wherein the wireless device receives data from the first node in aphysical downlink shared channel (PDSCH) and transmits the data to thesecond node in a physical uplink shared channel (PUSCH).
 18. The systemof communication of claim 17, wherein the first PDCCH, the first PHICH,and the PDSCH are multiplexed to be transmitted from the first node. 19.The system of communication of claim 17, wherein the second PUCCH andthe PUSCH are multiplexed to be transmitted to the second node.
 20. Thesystem of communication of claim 16, wherein the first PUCCH and thesecond PUCCH comprise at least one of: a sounding reference signal(SRS); an acknowledgment or no acknowledgment (ACK/NACK) signal; achannel quality indicator (CQI) signal; a precoding matrix indictor(PMI) signal; a rank indicator (RI) signal; or a scheduling requestindicator (SRI) signal.
 21. The system of communication of claim 16,wherein the first PDCCH and the second PDCCH comprise at least one of: adownlink grant signal; an uplink grant signal; a timing adjustmentsignal; or a transmission power control (TPC) signal.
 22. The system ofcommunication of claim 16, wherein the first node and the second nodeare time synchronized.
 23. The system of communication of claim 17,wherein the first node is selected to transmit the data using at leastone of received signal strength, bit error rate and word error rate. 24.The system of communication of claim 17, wherein the second node isselected to receive the data using at least one of received signalstrength, bit error rate and word error rate.